JP5712682B2 - Relay device and speaker device - Google Patents

Description

  The present invention relates to a relay device that relays an operation signal received from a remote operation device that remotely operates an external device, and a speaker device including the relay device.

  An electronic device such as an AV (AudioVisual) device can be remotely operated by a remote operation device (remote controller / hereinafter referred to as a remote controller) that outputs an infrared signal. In order to enable remote operation, it is necessary that an infrared signal receiver provided in the electronic device can receive an infrared signal output from the remote controller. For example, when an object is placed in front of the receiving unit or the electronic device is in a remote position, the receiving unit cannot receive an infrared signal from the remote controller, and the user cannot operate the electronic device with the remote control. .

  Patent Document 1 discloses a system that enables an electronic device in a position where a signal from a remote controller does not reach to be operated. The system described in Patent Document 1 has a configuration in which a relay device (also referred to as a repeater device) that relays a remote control signal is interposed between a remote control and an AV device such as a television or a video. When the user transmits a signal from the remote control to the relay device, the relay device transmits the signal received from the remote control to the AV device. Thereby, even if the remote control and the AV device are in a separated positional relationship, the user can operate the AV device with the remote control.

JP 09-275591 A

  However, the receiving unit provided in the electronic device is limited to some extent in the range in which infrared signals can be received from the remote controller. For this reason, the relay device that relays the signal of the remote controller must be installed in consideration of the signal reception range of the receiving unit of the electronic device.

  Accordingly, an object of the present invention is to enable easy installation without being aware of the positional relationship with an external device operated by a remote operation device, and to relay an operation signal from the remote operation device more accurately. It is providing a device and a speaker device.

The relay device according to the present invention is provided on one surface of the casing, and is different from one surface of the casing, with an operation signal receiving unit that receives an operation signal from a remote control device that remotely controls an external device. A relay device provided with a plurality of signal relay means for relaying the operation signal received by the operation signal receiving means to the outside, wherein the external device sends a response signal to the received control signal Output control means for outputting the control signal from any one of the plurality of signal relay means to the external device, and response signal receiving means for receiving a response signal from the external device, The output control means relays the operation signal from the signal relay means that output the control signal when the response signal receiving means receives the response signal .

In this configuration, since a plurality of signal relay means for relaying the operation signal are provided, the relay device is installed facing the external device, and the external device cannot receive the operation signal from the remote control device by the relay device. Even in this case, the signal can be relayed to the external device from any of the plurality of signal relay means. For this reason, the operator who installs the relay device can install the relay device without being aware of the positional relationship between the external device and the signal relay means. Further, in this configuration, the operation signal is relayed to the signal relay unit that outputs the control signal that can be received by the external device that is the relay destination of the operation signal. Depending on the positional relationship with the signal relay means, the external device may not be able to receive signals relayed by a plurality of signal relay means. For this reason, by using a control signal that causes the external device to output a response signal, for example, an HDMI-CEC command (High-Definition Multimedia Interface-Consumer Electronics Control), the signal relay means to be relayed is narrowed down to be received by the external device. It is possible to prevent the signal relay means installed at a position where it cannot be operated. As a result, power consumption can be reduced.

  In the relay device according to the present invention, when the response signal receiving unit receives a response signal as a result of the plurality of signal relay units outputting the control signal, the output control unit relays the operation signal. One of the relay means is selected, and the operation signal is set to be relayed from the selected signal relay means.

  In this configuration, the signal relay means for relaying the operation signal is selected. In this case, the signal relay means may be selected at random. Alternatively, the response signal receiving means may be selected to have a positional relationship of a plurality of signal relay means that output the control signal when receiving the response signal, for example, one located at the center of the plurality of signal relay means. Thereby, power consumption can be further reduced.

  The relay device according to the present invention further includes an adjustment unit that adjusts an output level of a signal that is output when the signal relay unit relays the operation signal, and the adjustment unit determines the output level by the external device. Adjust to the lowest level that can be received.

  In this configuration, power consumption can be reduced by adjusting the output level to the lowest level at which the relayed external device can receive the relayed signal.

  The relay device according to the present invention further includes storage means for storing a control signal for outputting the response signal, and the output control means causes the signal relay means to output the control signal stored in the storage means.

  According to this configuration, since the control signal that can be responded to by the external device is stored, it is possible to automatically identify the signal relay means that can relay the operation signal without receiving the operation signal. Is possible.

  In the relay device according to the present invention, the storage unit stores the operation signal received by the operation signal reception unit as a control signal.

  According to this configuration, by storing the received operation signal as a control signal, once the operation signal is received, it is possible to automatically specify the signal relay means for relaying the operation signal thereafter. .

  According to the present invention, the relay device can be easily installed without being aware of the positional relationship with the external device operated by the remote operation device, and the operation signal from the remote operation device can be relayed more accurately. it can.

The figure which shows the installation state of the speaker apparatus which concerns on Embodiment 1. FIG. Rear view of speaker device Schematic diagram for explaining the adjustment mode method Block diagram showing the hardware configuration of the speaker device 5 is a flowchart illustrating processing executed by the speaker device according to the first embodiment. 10 is a flowchart illustrating processing executed by the speaker device according to the second embodiment. 10 is a flowchart illustrating processing executed by the speaker device according to the third embodiment. Schematic which shows the structure of the speaker apparatus which concerns on Embodiment 4. FIG.

  The relay device according to the present invention receives an infrared signal (hereinafter referred to as infrared) of a remote control (remote control device) for a television (external device), and directs infrared including the same information to the infrared receiver of the television. This is a signal relay device that emits light. In the following description, it is assumed that the relay device according to the present invention is installed in front of the television so as to block the infrared light receiving unit of the television and is integrated with a speaker device that outputs the audio of the television.

  Note that the relay device according to the present invention may be integrated with other devices in addition to the speaker device, or may be a single relay device. In addition to the television, the external device that is the infrared relay destination by the relay device according to the present invention may be an audio stereo device or a recorder.

(Embodiment 1)
FIG. 1 is a diagram illustrating an installation state of the speaker device according to the first embodiment. The speaker device 1 according to this embodiment is installed in front of the television 100. FIG. 1A is a perspective view of a state in which the speaker device 1 is installed in front of the television 100, and FIG. 1B is a side view.

  The speaker device 1 and the television 100 are connected by an HDMI cable (not shown). The HDMI cable enables transmission of an HDMI-CEC command (response signal) in addition to transmission of an audio signal from the television 100 to the speaker device 1. The HDMI-CEC command includes, for example, a signal for controlling the volume from the remote controller 200 by the television 100, and this embodiment uses this HDMI-CEC command as a response signal.

  The television 100 includes a light receiving unit 102 that receives infrared light as an operation signal from a remote controller 200 for the television 100. The light receiving unit 102 is provided on a panel below the display screen 101. In the present embodiment, the speaker device 1 is provided so as to face the panel on which the light receiving unit 102 is provided. For this reason, the light receiving unit 102 is blocked by the speaker device 1 with respect to the infrared rays from the side facing the television 100 and cannot directly receive the infrared rays from the remote controller 200.

  The speaker device 1 has a rectangular parallelepiped housing 1A. The speaker device 1 has a front side of the television 100 such that the longitudinal direction of the housing 1A substantially coincides with the width direction of the television 100, and one surface of the housing 1A (hereinafter, this surface is referred to as the back surface) is the television 100 side. Is installed. At this time, the back surface of the housing 1A faces the panel on which the light receiving unit 102 of the television 100 is provided substantially in parallel. In the following, the surface of the housing 1A parallel to the back surface of the housing 1A is referred to as the front surface.

  The speaker device 1 includes a plurality of speakers 2A, 2B, 2C, 2D, and 2E. The speakers 2A to 2E are provided along the longitudinal direction of the front surface of the housing 1A. The speaker device 1 receives an audio signal from the television 100 via the HDMI cable, and emits sound to the front of the speaker device 1 through the speakers 2A to 2E.

  The speaker device 1 includes a light receiving unit 3 that receives infrared rays. The light receiving unit 3 is provided on the front surface of the housing 1A and receives infrared rays from the remote controller 200. Since the speaker device 1 is installed so as to block between the light receiving unit 102 of the television 100 and the remote control 200, the light receiving unit 3 of the speaker device 1 receives the infrared rays of the remote control 200 in place of the light receiving unit 102 of the television 100. To do.

  The speaker device 1 includes an LED (Light Emitting Diode) 4 for notification. The LED 4 emits light at a predetermined timing, and prompts the user (viewer of the television 100) to operate the remote controller 200. The operation of the remote control 200 is an operation of pressing any button of the remote control 200 such as a volume button or a channel button. In addition to the LED 4, a liquid crystal display screen may be provided on the front surface of the housing 1 </ b> A so that the user can more easily understand the operation of the remote controller 200 with characters. Further, sound may be output from the speakers 2A to 2E and prompted. In this case, the LED 4 may be omitted.

  FIG. 2 is a rear view of the speaker device 1. A plurality of infrared light emitting sections 5A, 5B, 5C, 5D, 5E, 5F, and 5G are provided along the longitudinal direction on the back surface of the housing 1A. The infrared light emitting units 5A to 5G emit infrared rays in a format that can be identified by the television 100, like the remote controller 200. The back surface of the housing 1 </ b> A faces the panel provided with the light receiving unit 102 of the television 100. Accordingly, at least one of the infrared light emitting units 5 </ b> A to 5 </ b> G is positioned opposite to or near the light receiving unit 102 of the television 100.

  When the light receiving unit 3 receives the infrared light from the remote controller 200, the infrared light emitting units 5A to 5G re-emit the same infrared light as the received infrared light as a signal output to the television 100. For example, when the remote controller 200 emits infrared light of a control signal for changing the volume of the television 100 and the speaker device 1 receives the infrared light, the infrared light emitting units 5A to 5G receive infrared light of the control signal for changing the volume of the television 100. Emits light.

  As a result, the light receiving unit 102 of the television 100 is blocked by the speaker device 1 and cannot directly receive infrared rays from the remote controller 200, but can receive infrared rays emitted from any of the infrared light emitting units 5A to 5G.

  The speaker device 1 executes an adjustment mode for determining which of the infrared light emitting units 5A to 5G emits infrared light. Some of the infrared light emitting units 5 </ b> A to 5 </ b> G are located away from the light receiving unit 102 of the television 100. Even if the infrared light emitting unit remote from the receiving unit 102 is caused to emit light, the receiving unit 102 cannot receive infrared rays, and thus wasteful power consumption occurs. Therefore, the speaker device 1 determines which of the infrared light emitting units 5A to 5G should emit light according to the adjustment mode.

  Hereinafter, the adjustment mode method will be described. FIG. 3 is a schematic diagram for explaining the adjustment mode method. In FIG. 3, the alternate long and short dash line from the infrared light emitting units 5 </ b> A to 5 </ b> B represents the infrared light emitting range, and the dotted line from the receiving unit 102 of the television 100 represents the light receiving range in which the receiving unit 102 can receive infrared light.

  When the adjustment mode is started, the control unit 10 of the speaker device 1 causes the LED 4 to emit light and prompts the user to operate the remote controller 200. When the remote controller 200 is operated by the user and infrared rays are emitted from the remote controller 200, the light receiving unit 3 receives the infrared rays. Then, the speaker device 1 emits infrared light (control signal) from the infrared light emitting unit 5A.

  The control unit 10 of the speaker device 1 prompts the user to operate the remote controller 200 by causing the LED 4 to emit light again after a predetermined time has elapsed since the infrared light emitting unit 5A emits light. When the light receiving unit 3 receives the infrared light from the remote controller 200, the speaker device 1 then causes the infrared light emitting unit 5B to emit the infrared light. The speaker device 1 repeats such an operation, and emits infrared rays one by one from the infrared light emitting units 5A to 5G.

  The order in which infrared rays are emitted from the infrared light emitting units 5A to 5G is not particularly limited, but in the following, the infrared light emitting unit 5A, the infrared light emitting unit 5B, the infrared light emitting unit 5C, the infrared light emitting unit 5D, the infrared light emitting unit 5E, and the infrared light emitting device. Infrared light is emitted in the order of the unit 5F and the infrared light emitting unit 5G.

  When the television 100 receives infrared rays from the speaker device 1, the television 100 performs an operation according to the received infrared rays. For example, when receiving infrared rays for adjusting the volume, the television 100 transmits an HDMI-CEC command for adjusting the volume as a response signal via the HDMI cable. When the HDMI-CEC command is received from the television 100, the speaker device 1 stores which of the infrared light emitting units 5A to 5G has received the HDMI-CEC command when emitting infrared light.

  In this embodiment, a signal conforming to the control indicated by the infrared ray received as the response signal is transmitted as an HDMI-CEC command. However, the present invention is not limited to this, and a signal indicating that the infrared ray is received or the received infrared ray is transmitted. A signal indicating the intensity may be transmitted as a response signal. Further, depending on the specifications of the television 100, there are cases in which all of the commands transmitted from the remote controller 200 cannot be transmitted as HDMI-CEC commands. In this case, a command that can be transmitted as an HDMI-CEC command can be used as a response signal.

  In the case of FIG. 3, the light receiving unit 102 of the television 100 can receive the infrared light emitted from the infrared light emitting units 5A to 5C, but cannot receive the infrared light emitted from the infrared light emitting units 5D to 5G. Therefore, when the infrared light from the remote controller 200 is input to the television 100, the speaker device 1 emits the infrared light from at least one of the infrared light emitting units 5A to 5C, and the infrared light emission control of the infrared light emitting units 5D to 5G is performed. Absent. As described above, in the adjustment mode, by specifying the infrared light emitting units 5D to 5G that are useless to emit infrared light and not performing the light emission control, useless power consumption can be eliminated.

  In the adjustment mode, when the receiving unit 102 of the television 100 can receive infrared rays from a plurality of infrared light emitting units, the speaker device 1 selects one of the plurality of infrared light emitting units. The selection method can be appropriately changed without any particular limitation. For example, when the receiving unit 102 can receive infrared rays from the infrared emitting units 5A to 5C, the infrared emitting unit 5B located in the middle may be selected, or the infrared emitting unit having the highest received infrared intensity is selected. Alternatively, the infrared light emitting unit 5A that first receives infrared light may be selected. Alternatively, one of the infrared light emitting units 5A to 5C may be selected at random.

  However, all the infrared light emitting units 5A to 5C may emit light, or when the receiving unit 102 of the television 100 can receive infrared rays from all the infrared light emitting units 5 to 5G, all the infrared light emitting units 5 to 5G are caused to emit light. Also good.

  Next, FIG. 4 is a block diagram showing a hardware configuration of the speaker device 1. The speaker device 1 includes a control unit 10, a storage unit 11, a light emission control unit 12, an HDMI communication unit 13, and the like in addition to the speakers 2A to 2E, the light receiving unit 3, the LED 4, and the infrared light emitting units 5A to 5G described above.

  The control unit 10 controls the operation of the speaker device 1 by executing a program stored in the storage unit 11. The storage unit 11 stores a program executed by the control unit 10, processing results of the control unit 10, for example, information on the infrared light emitting units 5A to 5G to be controlled for light emission determined in the adjustment mode.

  The light emission control unit 12 performs light emission control of the LED 4 and the infrared light emitting units 5A to 5G. The HDMI communication unit 13 communicates with the television 100 via an HDMI cable. In the present embodiment, as described above, the HDMI communication unit 13 receives an audio signal and an HDMI-CEC command from the television 100.

  FIG. 5 is a flowchart showing processing executed by the speaker device 1. The process illustrated in FIG. 5 is executed by the control unit 10.

  The control unit 10 determines whether or not to start the adjustment mode (S1). The timing for starting the adjustment mode may be when the power of the speaker device 1 is turned on or when the start operation is performed by the user. When the adjustment mode is not started (S1: NO), the control unit 10 ends this process. When starting the adjustment mode (S1: YES), the control unit 10 causes the LED 4 to emit light and prompts the user to operate the remote controller 200 (S2).

  The control unit 10 determines whether or not infrared rays are received from the remote controller 200 (S3). When light is not received (S3: NO), the control unit 10 stands by until light is received. At this time, if the infrared ray is not received even after a predetermined time has elapsed, the control unit 10 may end the present process or may shift to another process (for example, the process of S2).

  When the infrared ray is received (S3: YES), the control unit 10 causes the light emission control unit 12 to perform emission control of one of the infrared light emission units 5A to 5G to emit the infrared ray that the television 100 can respond to (S4). The control unit 10 determines whether an HDMI-CEC command has been received from the television 100 (S5). When the HDMI-CEC command is received from the television 100 (S5: YES), the control unit 10 stores information for specifying the infrared light emitting units 5A to 5G emitted in S4 in the storage unit 11 (S7), and the process of S8 Move on.

  When the HDMI-CEC command has not been received (S5: NO), the control unit 10 determines whether or not a predetermined time has elapsed since the infrared light was emitted from one of the infrared light emitting units 5A to 5G in S4. (S6). When the predetermined time has not elapsed (S6: NO), the control unit 10 returns to the process of S5. When the predetermined time has elapsed (S6: YES), the control unit 10 proceeds to the process of S8.

  The control unit 10 determines whether there is an infrared light emitting unit 5A to 5G that has not yet emitted infrared light (S8). When there is an infrared light emitting unit 5A to 5G that has not yet emitted infrared rays (S8: YES), the control unit 10 returns to the process of S2, and the same processing is performed for the other infrared light emitting units 5A to 5G. Do. For example, when the control unit 10 performs the process for the infrared light emitting unit 5A, the control unit 10 performs the same process for the infrared light emitting unit 5B.

  When there is no infrared light emitting unit 5A to 5G that does not emit infrared light (S8: NO), the control unit 10 is suitable for emitting infrared light from the infrared light emitting unit in which the information specified in S7 is stored. Is selected (S9). When only the information of one infrared light emitting unit is stored in the storage unit 11, the control unit 10 is suitable for the infrared light emitting unit to emit infrared light. When information on a plurality of infrared light emitting units is stored in the storage unit 11, the control unit 10 selects one of them.

  After the process of S9, the control unit 10 ends this process. After finishing the adjustment mode of this process, when the control unit 10 receives infrared rays from the remote controller 200, the control unit 10 causes the television 100 to re-emit infrared rays received from the infrared light emitting unit selected in S9.

  Note that the control unit 10 may minimize the light emission level of the infrared light emitting unit. In this case, after specifying the infrared light emitting section to emit light, the light emission level is lowered stepwise, and the processes after S2 are executed again. And the control part 10 sets the light emission level of an infrared rays light emission part to the final light emission level which the television 100 was able to light-receive. As a result, power consumption can be reduced without increasing the infrared emission level more than necessary.

  In the process shown in FIG. 5, when the television 100 receives infrared rays from a plurality of infrared light emitting units, any one is selected in the process of S <b> 9. For example, the control unit 10 receives in the adjustment mode. The infrared light may be emitted from all infrared light emitting units that have emitted infrared light that can be received by the unit 102.

  Further, when the infrared light is emitted from a plurality of infrared light emitting units, the control unit 10 may cause the infrared light to be emitted with a minimum light quantity. In this case as well, power consumption can be suppressed by reducing the amount of infrared light to the minimum necessary.

  In the adjustment mode, when the television 100 can receive infrared rays from a plurality of infrared emission units, the control unit 10 causes the infrared emission units to emit light again, and further narrows down the infrared emission units. Also good. For example, when the television 100 can receive infrared rays from the infrared light emitting units 5A, 5B, and 5C, the control unit 10 lowers the light emission level and causes the infrared light emitting units 5A, 5B, and 5C to emit light again. At this time, when the television 100 cannot receive the infrared light from the infrared light emitting unit 5A, the control unit 10 excludes the infrared light emitting unit 5A from the target of light emission control. Hereinafter, by repeating this, the infrared light emitting unit closest to the receiving unit 102 of the television 100 can be further narrowed down.

(Embodiment 2)
Next, Embodiment 2 will be described. The second embodiment is different from the first embodiment in which the user is requested to operate the remote controller 200 each time the infrared light emitting units 5A to 5G emit light, in that the user operates the remote controller 200 only once in the adjustment mode. Hereinafter, only the difference will be described, and the description of the same configuration and function as those of the first embodiment will be omitted.

  FIG. 6 is a flowchart illustrating processing executed by the speaker device 1 according to the second embodiment. Since the configuration of the speaker device 1 is the same as that of the first embodiment, the description thereof is omitted. The process shown in FIG. 6 is executed by the control unit 10.

  The control unit 10 determines whether or not to start the adjustment mode (S11). When the adjustment mode is not started (S11: NO), the control unit 10 ends this process. When starting the adjustment mode (S11: YES), the control unit 10 causes the LED 4 to emit light and prompts the user to operate the remote controller 200 (S12).

  The control unit 10 determines whether infrared light is received from the remote controller 200 (S13). If no light is received (S13: NO), the control unit 10 stands by until light is received. When the infrared ray is received (S13: YES), the control unit 10 stores the received infrared information in the storage unit 11 (S14).

  Next, the control unit 10 causes the light emission control unit 12 to control light emission of one of the infrared light emitting units 5A to 5G, and re-emits the received infrared light based on the information stored in the storage unit 11 in S14 (S15). . The control unit 10 determines whether an HDMI-CEC command is received from the television 100 (S16). When the HDMI-CEC command is received from the television 100 (S16: YES), the control unit 10 stores information for identifying the infrared light emitting units 5A to 5G emitted in S4 in the storage unit 11 (S17), and the process of S19 Move on.

  When the HDMI-CEC command has not been received (S16: NO), the control unit 10 determines whether or not a predetermined time has elapsed since the infrared light was emitted from one of the infrared light emitting units 5A to 5G in S14. (S18). When the predetermined time has not elapsed (S18: NO), the control unit 10 returns to the process of S15. When the predetermined time has elapsed (S18: YES), the control unit 10 proceeds to S19.

  The control unit 10 determines whether there is an infrared light emitting unit 5A to 5G that has not yet emitted infrared light (S19). When there is an infrared light emitting unit 5A to 5G that has not yet emitted infrared rays (S19: YES), the control unit 10 returns to the process of S15, and the same processing is performed for the other infrared light emitting units 5A to 5G. Do.

  When there are no infrared light emitting units 5A to 5G that have not yet emitted infrared light (S19: NO), the control unit 10 emits infrared light from the infrared light emitting unit in which the information specified in S17 is stored. A suitable one is selected (S20). Thereafter, the control unit 10 ends this process.

  As described above, in the second embodiment, if the user operates the remote controller 200 only once at the start of the adjustment mode, infrared light is automatically emitted thereafter, so that the user's trouble in the adjustment mode can be saved.

(Embodiment 3)
Next, Embodiment 3 will be described. In the third embodiment, infrared information that can operate the television 100 is stored in the storage unit 11 in advance, and when the adjustment mode is started, the infrared information stored in the storage unit 11 is transmitted from the infrared light emitting units 5 to 5. Light is emitted from 5G. That is, the third embodiment is different from the first and second embodiments in that the user does not operate the remote controller 200 in the adjustment mode. Hereinafter, only the difference will be described, and the description of the same configuration and function as those of the first embodiment will be omitted.

  FIG. 7 is a flowchart illustrating processing executed by the speaker device 1 according to the third embodiment. The speaker device 1 according to the third embodiment has a configuration that does not include the LED 4 described in the first embodiment. The process illustrated in FIG. 7 is executed by the control unit 10.

  The control unit 10 determines whether or not to start the adjustment mode (S21). When the adjustment mode is not started (S21: NO), the control unit 10 ends this process. When starting the adjustment mode (S21: YES), the control unit 10 causes the light emission control unit 12 to perform light emission control of one of the infrared light emission units 5A to 5G, and includes infrared light (for example, information previously stored in the storage unit 11). , Volume adjustment) is emitted (S22).

  The control unit 10 determines whether an HDMI-CEC command is received from the television 100 (S23). When the HDMI-CEC command is received from the television 100 (S23: YES), the control unit 10 stores information for specifying the infrared light emitting units 5A to 5G emitted in S22 in the storage unit 11 (S25), and the process of S26 Move on.

  When the HDMI-CEC command has not been received (S23: NO), the control unit 10 determines whether or not a predetermined time has elapsed since the infrared light was emitted from one of the infrared light emitting units 5A to 5G in S22. (S24). When the predetermined time has not elapsed (S24: NO), the control unit 10 returns to the process of S23. When the predetermined time has elapsed (S23: YES), the control unit 10 proceeds to the process of S26.

  The control unit 10 determines whether there is an infrared light emitting unit 5A to 5G that has not yet emitted infrared light (S26). When there is an infrared light emitting unit 5A to 5G that has not yet emitted infrared rays (S26: YES), the control unit 10 returns to the process of S23, and the same processing is performed for the other infrared light emitting units 5A to 5G. Do.

  When there are no infrared light emitting units 5A to 5G that have not yet emitted infrared light (S26: NO), the control unit 10 emits infrared light from the infrared light emitting unit in which the information specified in S25 is stored. A suitable one is selected (S27). Thereafter, the control unit 10 ends this process.

  As described above, in the third embodiment, since the user does not need to operate the remote controller 200 in the adjustment mode, for example, the speaker device 1 can start the adjustment mode as soon as the power is turned on. Can be saved.

  Embodiments 2 and 3 may be combined. Specifically, when the storage unit 11 does not store infrared rays that can operate the television 100 connected to the speaker device 1, the LED 4 is caused to emit light to prompt the user to operate the remote controller 200. Infrared information from the remote controller 200 is stored in the storage unit 11, and thereafter, the stored infrared light is emitted in the adjustment mode.

(Embodiment 4)
Embodiment 4 will be described below. The speaker device 1 according to the present embodiment is configured such that the number of infrared light emitting units that emit infrared light can be reduced as compared with the first to third embodiments. Since the operation of the speaker device 1 according to the fourth embodiment is the same as that of the first to third embodiments, the description thereof is omitted.

  FIG. 8 is a schematic diagram illustrating a configuration of the speaker device 1 according to the fourth embodiment. FIG. 8A is a rear view of the housing 1A, and FIG. 8B is a perspective view of the housing 1A viewed from above.

  A plurality of holes 10 </ b> A, 10 </ b> B, 10 </ b> C, and 10 </ b> D are formed on the back surface of the housing 1 </ b> A of the speaker device 1 along the longitudinal direction. Inside the housing 1A, there are formed inclined surfaces 11A, 12A that form a hole 10A and face each other in parallel. In addition, inclined surfaces 11B and 12B that form a hole 10B and face each other in parallel are formed inside the housing 1A. The inclined surfaces 11A and 11B are inclined in directions opposite to each other.

  An infrared light emitting unit 6A is provided at a position facing the inclined surfaces 11A and 11B. The infrared light emitted by the infrared light emitting unit 6A is reflected by the inclined surfaces 11A and 11B and the inclined surfaces 12A and 12B and output to the outside from the holes 10A and 10B, as indicated by the dotted arrows in the figure.

  Similarly, on the inner side of the housing 1A, inclined surfaces 11C and 12C that form a hole 10C and face each other in parallel are formed, and inclined surfaces 11D and 12D that form a hole 10D and face each other in parallel are formed. ing. The inclined surfaces 11C and 11D are inclined in directions opposite to each other. An infrared light emitting unit 6B is provided at a position facing the inclined surfaces 11C and 11D. The infrared light emitted from the infrared light emitting unit 6B is reflected by the inclined surfaces 11C and 11D and the inclined surfaces 12C and 12D as shown by the dotted arrows in the figure, and is output to the outside from the holes 10C and 10D.

  Thus, in this embodiment, infrared rays can be output from the four holes 10A to 10D with the two infrared light emitting portions 6A and 6B by refracting the infrared rays from the infrared light emitting portions 6A and 6B. That is, the two infrared light emitting units 6A and 6B can have the same configuration as the four infrared light emitting units, and the number of infrared light emitting units can be reduced.

  The specific configuration and the like of the speaker device 1 described above can be appropriately changed in design, and the actions and effects described in the above-described embodiment are merely a list of the most preferable actions and effects that arise from the present invention. The operations and effects of the present invention are not limited to those described in the above embodiment.

  In the above-described embodiment, the speaker device 1 is described as being configured to be connected to an external device such as the television 100 via HDMI. However, the speaker device 1 can be made to respond to an external device such as USB (Universal Serial Bus) or RS-232C. I just need it.

1-speaker device (relay device)
1A—Cases 2A to 2E—Speaker (audio output means)
3-Receiving unit (operation signal receiving means)
5A-5G-Infrared light emitting part (signal relay means)
10-control unit (output control means)
12-light emission control unit (output control means, adjustment means)
13-HDMI communication unit (response signal receiving means, audio signal receiving means)
100-TV 102-Light receiving unit 200-Remote control (remote control device)

Claims (7)

A housing, an operation signal receiving means for receiving an operation signal from a remote operation device for remotely operating an external device, and a surface different from the one surface of the housing; A relay device comprising a plurality of signal relay means for relaying the operation signal received by the operation signal receiving means to the outside,
The external device outputs a response signal to the received control signal,
Output control means for outputting the control signal from any one of the plurality of signal relay means to the external device;
Response signal receiving means for receiving a response signal from the external device;
Further comprising
The output control means includes
A relay apparatus configured to relay the operation signal from the signal relay unit that output the control signal when the response signal receiving unit receives the response signal. As a result of the plurality of signal relay means outputting the control signal, when the response signal receiving means receives the response signal,
The output control means includes
The relay apparatus according to claim 1 , wherein any one of the signal relay units that relay the operation signal is selected, and the operation signal is relayed from the selected signal relay unit. An adjustment means for adjusting an output level of a signal output when the signal relay means relays the operation signal;
The adjusting means includes
The output level, the relay device according to claim 1 or 2, wherein the external device is adjusted to the lowest level that can be received. A storage means for storing a control signal for outputting the response signal;
The relay apparatus according to any one of claims 1 to 3 , wherein the output control unit outputs the control signal stored in the storage unit from the signal relay unit. The relay device according to claim 4 , wherein the storage unit stores the operation signal received by the operation signal reception unit as a control signal. A relay device according to any one of claims 1 to 5 ;
An audio signal receiving means for receiving an audio signal from the outside ;
And sound output means for outputting as sound a voice signal the audio signal received by the receiving means,
A speaker device comprising: A housing, an operation signal receiving means for receiving an operation signal from a remote operation device for remotely operating an external device, and a surface different from the one surface of the housing; A relay device having a plurality of signal relay means for relaying the operation signal received by the operation signal receiving means to the outside ;
An audio signal receiving means for receiving an audio signal from the outside ;
And sound output means for outputting as sound a voice signal the audio signal received by the receiving means,
A speaker device comprising:

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